The Tevatron in Collider Run II (2001–present) is operating with 6 times more bunches, many times higher beam intensities and luminosities than in Run I (1992–1995). Electromagnetic long-range and head-on interactions of high intensity proton and antiproton beams have been significant sources of beam loss and lifetime limitations. We present observations of the beam-beam phenomena in the Tevatron and results of relevant beam studies. We analyze the data and various methods employed in operations, predict the performance for planned luminosity upgrades, and discuss ways to improve it
The challenge of achieving the Tevatron Run II luminosity goal of 3 {center_dot} 10{sup 32} cm{sup -...
Before the Tevatron Collider Run II ended in September of 2011, a number of specialized beam study p...
The Fermilab accelerator complex is in the middle of an upgrade plan Fermilab III. In the last phase...
The Tevatron in Collider Run II (2001-present) is operating with 6 times more bunches, many times hi...
For almost a quarter of a century, the Tevatron proton-antiproton collider was the centerpiece of th...
Long-range beam-beam effects occurred in the Tevatron at all stages (injection, ramp, squeeze, and c...
Electromagnetic long-range and head-on interactions of high intensity proton and antiproton beams ar...
The long-range beam-beam interactions limit the achievable luminosity in the Tevatron. During the pa...
Abstract. The Tevatron in Collider Run is operating with six times more bunches and many times highe...
Since the inauguration of colliding proton-antiproton operations in 1987, the Tevatron has exhibited...
The Tevatron in Run II is operating with three trains of 12 bunches each. Long-range beam-beam inter...
Beam-beam phenomena have until now limited the beam currents and luminosity achievable in the Tevatr...
The performance of the Tevatron collider demonstrated continuous growth over the course of Run II, w...
In the first stage of Run II, the Tevatron will be operated with 36 bunches in each beam with bunch ...
Applying the space-charge forces of a low-energy electron beam can lead to a significant improvement...
The challenge of achieving the Tevatron Run II luminosity goal of 3 {center_dot} 10{sup 32} cm{sup -...
Before the Tevatron Collider Run II ended in September of 2011, a number of specialized beam study p...
The Fermilab accelerator complex is in the middle of an upgrade plan Fermilab III. In the last phase...
The Tevatron in Collider Run II (2001-present) is operating with 6 times more bunches, many times hi...
For almost a quarter of a century, the Tevatron proton-antiproton collider was the centerpiece of th...
Long-range beam-beam effects occurred in the Tevatron at all stages (injection, ramp, squeeze, and c...
Electromagnetic long-range and head-on interactions of high intensity proton and antiproton beams ar...
The long-range beam-beam interactions limit the achievable luminosity in the Tevatron. During the pa...
Abstract. The Tevatron in Collider Run is operating with six times more bunches and many times highe...
Since the inauguration of colliding proton-antiproton operations in 1987, the Tevatron has exhibited...
The Tevatron in Run II is operating with three trains of 12 bunches each. Long-range beam-beam inter...
Beam-beam phenomena have until now limited the beam currents and luminosity achievable in the Tevatr...
The performance of the Tevatron collider demonstrated continuous growth over the course of Run II, w...
In the first stage of Run II, the Tevatron will be operated with 36 bunches in each beam with bunch ...
Applying the space-charge forces of a low-energy electron beam can lead to a significant improvement...
The challenge of achieving the Tevatron Run II luminosity goal of 3 {center_dot} 10{sup 32} cm{sup -...
Before the Tevatron Collider Run II ended in September of 2011, a number of specialized beam study p...
The Fermilab accelerator complex is in the middle of an upgrade plan Fermilab III. In the last phase...